An apparatus for registering film in a drum scanner assembly including; a concave curved film platen having spaced first and second linear edges that are oriented horizontally and third and fourth curved side edges connected between the first and second edges, the concave, curved film platen having a curved surface defining a curved film path having a first downwardly curved position and a second upwardly curved position from the first to the second edges, first and second spaced film engagement assemblies independently and movably mounted relative to the platen at the second portion of the film path, the assemblies having film registration slides for engaging the leading edge of a sheet of film fed onto the concave, curved film platen from the first edge and along the curved film path the slides being mounted for movement over substantially the length of the second portion of the path and being adapted to register films of different lengths; and device associated with the slides for biasing the slides through the force of gravity against the leading edge of the film, wherein as the film is fed along the curved path, the slides are moved upwardly by the film against the force of gravity wherein the film is caused to conform to the curved film platen and wherein the independently mounted slides act to remove skew from the fed film.
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1. An apparatus for registering film in a drum scanner assembly comprising;
a concave curved film platen having spaced first and second linear edges that are oriented horizontally and third and fourth curved side edges connected between said first and second edges, said concave, curved film platen having a curved surface defining a curved film path having a first downwardly curved position and a second upwardly curved position from said first to said second edges, first and second spaced film engagement assemblies independently and movably mounted relative to said platen at said second portion of said film path, said assemblies having film registration slides for engaging the leading edge of a sheet of film fed onto said concave, curved film platen from said first edge and along said curved film path said slides being mounted for movement over substantially the length of said second portion of said path and being adapted to register films of different lengths; and means associated with said slides for biasing said slides through the force of gravity against said leading edge of said film, wherein as said film is fed along said curved path, said slides are moved upwardly by said film against the force of gravity wherein said film is caused to conform to the curved film platen and wherein said independently mounted slides act to remove skew from said fed film.
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This invention relates in general to internal drum scanner assemblies and laser imaging systems incorporating such scanner assemblies. In particular, the present invention relates to a mechanism for aligning film into a scanning position in an internal drum type scanner assembly, suitable for use in a medical imaging system.
Laser imaging systems are commonly used to produce photographic images from digital image data generated by magnetic resonance (MR), computed tomography (CT) or other types of medical image scanners. Systems of this type typically include a continuous tone laser imager for exposing the image on photosensitive film, a film processor for developing the film, and control subsystems for coordinating the operation of the laser imager and the film processor.
The digital image data is a sequence of digital image values representative of the scanned image. Image processing electronics within the control subsystem processes the image data values to generate a sequence of digital laser drive values (i.e., exposure values), which are input to a laser scanner. The laser scanner is responsive to the digital laser drive values for scanning across the photosensitive film in a raster pattern for exposing the image on the film.
The continuous-tone images used in the medical imaging field have very stringent image-quality requirements. A laser imager printing onto transparency film exposes an image in a raster format, the line spacing of which must be controlled to better than one micrometer. In addition, the image must be uniformly exposed such that the observer cannot notice any artifacts. In the case of medical imaging, the observers are professional image analysts (e.g., radiologists).
Film exposure systems are used to provide exposure of the image on photosensitive film. Known film exposure systems include a linear translation system and a laser or optical scanning system. The laser scanning system includes a laser scanner with unique optical configurations (i.e., lenses and mirrors) for exposure of the image onto the film. The linear translation system provides for movement of the laser scanning system in a direction perpendicular to the scanning direction, such that a full image may be scanned on a piece of photosensitive film.
In an internal drum type laser scanner assembly, a piece of film is positioned onto a film platen, wherein the film platen has a partial cylindrical or partial drum shape. The photosensitive film is positioned against the film platen. The laser or optical scanning system is positioned at the center of curvature of the photosensitive film for scanning a scan line across the photosensitive film surface. A linear translation system moves the laser or optical scanning system lengthwise along a longitudinal axis as defined by the center of curvature of the film to expose an entire image onto the film.
The film may be fed onto the film platen utilizing a film transport system which often incorporates a plurality of feed rollers. Once the piece of photosensitive film is fed onto the film platen, the film must be held tight against the curved surface of the film platen, and centered and aligned into a scanning position in order for an image to be correctly exposed onto the photosensitive film. Any skew of the film must also be removed. Often such methods and mechanisms for aligning and centering a piece of film on the internal surface of the film platen require multiple complex mechanical and electrical components and control systems.
U.S. Pat. No. 5,956,071, issued Sep. 21, 1999, inventors Mattila et al., discloses an assembly for positioning a film into a scanning position on a curved film platen in an internal drum scanner assembly. The film platen is defined by a first curved edge, a second curved edge, a film feed edge, and a film stop edge. The assembly comprises a first slider block assembly and a second slider block assembly which is spaced from the first slider block assembly a distance less than the width of the leading edge of the photosensitive film. A feed mechanism is positioned proximate the film feed edge, for feeding a piece of photosensitive film having a leading edge along the curved film platen. The leading edge of the film is fed from a location proximate the film feed edge towards the film stop edge. When the photosensitive film is in the scanning position, the leading edge of the photosensitive film contacts the first slider assembly and the second slider assembly. The photosensitive film is tensioned against the curved film platen in alignment between the first slider assembly and the second slider assembly and the feed mechanism, thus removing any skew.
As disclosed in the previous patent, different film sizes are accommodated by a set of a first and second slider block assemblies being provided for each film size handled by the scanner assembly. The slider block assembly sets are spaced along the curved length of the platen since different film lengths wrap around the platen to varying degrees. Although useful for the purposes for which it was intended, this arrangement adds undesirable complexity in that it requires changing slider block assembly locations for each film size.
There is thus a need in an internal drum type laser scanner assembly to provide a system for properly registering multiple film sizes within the drum that is reliable, low in cost and simple in design.
According to the present invention, there is provided a solution to the problems and need discussed above.
An apparatus for registering film in a drum scanner assembly comprising;
a concave curved film platen having spaced first and second linear edges that are oriented horizontally and third and fourth curved side edges connected between said first and second edges, said concave, curved film platen having a curved surface defining a curved film path having a first downwardly curved position and a second upwardly curved position from said first to said second edges, first and second spaced film engagement assemblies independently and movably mounted relative to said platen at said second portion of said film path, said assemblies having film registration slides for engaging the leading edge of a sheet of film fed onto said concave, curved film platen from said first edge and along said curved film path said slides being mounted for movement over substantially the length of said second portion of said path and being adapted to register films of different lengths; and
means associated with said slides for biasing said slides through the force of gravity against said leading edge of said film, wherein as said film is fed along said curved path, said slides are moved upwardly by said film against the force of gravity wherein said film is caused to conform to the curved film platen and wherein said independently mounted slides act to remove skew from said fed film.
The invention has the following advantages.
1. Handles multiple film sizes.
2. Precise control of motion of film registration mechanism.
3. Reliability.
4. Ease of assembly.
Photosensitive film is stored within the film supply mechanism 32. The film transport system 40 allows the photosensitive film to be moved between the film exposure assembly 34, film processing station 36, and the film receiving area 38. The film transport system 40 may include a roller system (not shown) to aid in transporting the film along a film transport path, indicated by dashed line 44. The direction of film transport along film transport path 44 is indicated by arrows 46. In particular, the film supply mechanism 32 includes a mechanism for feeding a piece of film along film transport path 44 into the film exposure assembly 34 for exposing the desired image on the photosensitive film using a laser or optical scanner assembly. After exposure of the desired image on the photosensitive film, the photosensitive film is moved along the film transport path 44 to the film processing station 36. The film processing station 36 develops the image on the photosensitive film. After film development, the photosensitive film is transported to the film receiving area 38.
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention.
Drum frame 54 is constructed of metal, and includes a first end 62, a second end 64, a first side 66, a second side 68, a bottom 70, and a top 72. Film platen 55 is positioned within the drum frame 54. Film platen 55 provides a cylindrical or partially cylindrically-shaped scanning surface.
The linear translation system 52 positions the optical scanner assembly 50 along the center of curvature (of a piece of film in scanning position on the film platen), coincident with longitudinal axis 56. In particular, the linear translation system 52 is positioned between the first end 62 and the second end 64.
Referring to
A piece of photosensitive film 76 is shown positioned on the concave, curved film platen 55. During exposure of the photosensitive film 76, the photosensitive film 76 is held against the film platen 55 in a scanning position. In a scanning position the photosensitive film 76 assumes the shape of the curved film platen 55, which has a cylindrical, partial cylindrical, or drum shape. The photosensitive film 76 is positioned in a scanning position (i.e., aligned and centered) using the film positioning mechanism in accordance with the present invention.
In the scanning position, the photosensitive film 76 is aligned (skew removed), centered and held against the film platen 55. The film is aligned when the leading and trailing edges of film 76 are parallel to longitudinal axis 56. The optical scanner assembly 50 scans a laser beam representative of an image to be exposed on the film, across the film scanning surface in an image-wise pattern. In particular, the scanning laser beam (indicated at 78) emanates radially from the center of curvature 56 of the film platen 55 and film 76, which is located along the center of curvature of longitudinal axis 56. The optical scanner assembly 50 scans the laser beam containing image data representative of the image to be exposed in raster lines by rotating about the longitudinal axis 56 of the cylinder drum (indicated by directional arrow 80). As the optical scanner assembly 50 scans the image and raster lines in an image-wise pattern across the photosensitive film 76 located on the internal surface of platen 55, the linear translation system 52 moves the optical scanner assembly 50 along the center of curvature longitudinal axis 56 to expose a full image on the photosensitive film. The linear translation system 52 moves the optical scanner assembly 50 along the longitudinal axis 56 in a direction which is generally perpendicular to the scanning direction of laser beam 78. Since the linear translation system 52 moves the optical scanner assembly 50 during each scan line, the resulting scan lines may not be perpendicular, but are "generally" perpendicular to the direction of movement of the linear translation system.
In one exemplary embodiment, the film exposure area on the internal film platen surface is 17 inches by 14 inches, suitable for exposure of a 17 inch by 14 inch piece of photosensitive film. In the exemplary embodiment disclosed herein, the film is exposed in a vertical direction. In particular, since the film is fed into the exposure module in the 14 inch direction and subsequently scanned in the 17 inch direction, the scanned raster lines appear in the vertical direction. The laser beam is scanned 180°C (or greater than 180°C) across the internal drum surface, for exposure of 17 inches across the photosensitive film. The linear translation system moves the optical scanner assembly along the longitudinal axis located at the center of curvature of the internal film platen surface to cause fall exposure of a desired image/images on the photosensitive
The photosensitive film can be a photosensitive film which is sensitive to laser beam light. The film can be a light sensitive photothermographic film having a polymer or paper base coated with an emulsion of dry silver or other heat sensitive material. The photosensitive film can also be any other type of film, such as wet processed photosensitive film.
A mechanism in accordance with the present invention for positioning a piece of photosensitive film into a scanning position on a curved film platen of an internal drum scanner assembly will be described in detail in the following paragraphs. The mechanism aligns the photosensitive film, while holding or compressing the photosensitive film against the curved film platen in the scanning position, allowing an image to be precisely exposed on the photosensitive film.
Referring now to
As shown more clearly in
Concave, curved film platen 55, shown in
A roller bumper 144 is mounted at the lower end 146 of track 136 by means of screw 148. As shown in
Film engagement assemblies 102, 104 operate as follows. The film registration slides 118, 120 is at rest in engagement with bumper 144 due to the force of gravity on weights 126, 128. As film 76 is fed onto platen 55, it wraps around platen 55 and engages lips 121 of film registration slide 118, 120 protruding through arcuate slots 150 in platen 55. The beam strength of film 76 allows it to push the slides 118,120 up tracks 136 while the weight of slides 118,120 holds film 76 flat against the imaging surface of platen 55. Tracks 136 are machined to be concentric with platen 55 so that as film 76 pushes against slides 118, 120 there is no relative motion between the film engagement assembly lip 121 and the film 76. This prevents the leading edge of film 76 from lifting up off the platen 55, which could cause the image at that location to be out of focus. As film 76 is fed, it pushes slides 118, 120 ahead of it.
If film 76 is skewed as it is fed onto platen 55 by rollers 100, one of slides 118, 120 will travel further in its track than the other until the trailing edge of film 76 reaches rollers 100 (see FIG. 4). This is illustrated in
In the current embodiment, the slides can operate over a range of nearly ninety degrees in the drum, allowing for multiple film lengths. The range of film sizes the slides can accommodate depends on the radius of the drum. For the system being described, the range of force imparted to the film lies between 0.1 and 0.6 pounds of force per slide mechanism. Because the angle of the film changes with respect to the weights as it wraps around the drum surface, it should be noted that the weights provide a different retaining force to the film for each separate film length. It is important to note the system must sufficiently overcome the friction between the film and the drum surface in order to register the film against the feed rollers.
As disclosed in U.S. Pat. No. 5,956,071, a centering mechanism can be provided to center film 76 on platen 55.
As shown in
Referring now to
Slides 170 operate independently of each other and function in the same manner as slides 118, 120 in registering film 76 on platen 55.
PARTS LIST | ||
30 | laser imaging system | |
32 | film supply mechanism | |
34 | film exposure assembly | |
36 | film processing station | |
38 | film receiving area | |
40 | film transport system | |
42 | imaging system housing | |
44,46 | film transport path | |
50 | optical scanner assembly | |
52 | linear translation system | |
54 | drum frame | |
55 | curved film platen | |
56 | drum longitudinal | |
58 | scanning direction | |
59 | direction arrow | |
60 | directional arrow | |
62 | first end | |
64 | second end | |
66 | first side | |
68 | second side | |
70 | bottom | |
72 | top | |
76 | photosensitive film | |
78 | scanning laser beam | |
80 | directional arrow | |
100 | feed rollers | |
101 | trailing edge | |
102,104 | film engagement assemblies | |
106,108 | direction of rotation | |
118,120 | film registration slides | |
121 | film engagement assembly lip | |
122 | body | |
124,130 | fasteners | |
126,128 | weights | |
132 | split wheels | |
134 | shafts | |
136 | track | |
138 | curved plot | |
140 | rail | |
142 | rail ridge | |
144 | roller bumper | |
146 | lower end | |
148 | screw | |
150 | arcuate slots | |
170 | film registration slides | |
172 | film slots | |
174 | film registration slide body | |
176 | front surface | |
178,180 | upper wheel sets | |
182 | lower wheel set | |
184 | fasteners | |
186 | weights | |
200,202 | platen linear edges | |
204,206 | platen curved edges | |
208 | inner curved surface | |
210 | downwardly curved position | |
212 | upwardly curved position | |
Johnson, Benjamin A., Nelson, Brian D.
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